Rotary energy converter with retractable barrier

ABSTRACT

A rotary internal combustion engine includes an outer housing and an inner housing defining an enclosure therebetween, and first and second side housings disposed on opposite sides of the outer housing. At least one of the outer and inner housings is rotatable relative to the other and at least two barriers are disposed in the enclosure and divide the enclosure into a combustion chamber and an exhaust chamber. At least one barrier is rotatable relative to at least one other barrier and at least one barrier comprises a retractable barrier mounted along a pivot axis and is pivotable between an extended position and a retracted position. An intake port, exhaust port, and ignition source are also provided. The rotary internal combustion engine further includes an intake opening formed in one of the side housings. The intake opening is intermittently fluidly communicating with the combustion chamber through the intake port.

CROSS-REFERENCE TO RELATED APPLICATION AND CLAIM TO PRIORITY

This application is a continuation of application Ser. No. 13/644,705,filed Oct. 4, 2012, which is a continuation of application Ser. No.12/349,122, filed Jan. 6, 2009, now U.S. Pat. No. 8,286,609, thedisclosures of which are incorporated herein by reference and to whichpriority is claimed.

FIELD OF THE INVENTION

The present disclosure relates to energy producing and transferringdevices and in particular, to internal combustion rotary engines androtary energy converters.

BACKGROUND OF THE INVENTION

Internal combustion engines perform useful work by combusting a fuel andproducing expanding hot gases that act directly on and thereby moveparts of the engine. Typically, the steps involved in internalcombustion include 1) the intake of a vaporized fuel and an oxidizer(typically air); 2) the compression of the oxidizer; 3) the ignition ofthe vaporized fuel and oxidizer; 4) the combustion of the fuel and theexpansion of the resulting gases which act on the engine part; and 5)the exhaust of the combustion gases. A variety of types of internalcombustion engines exist, including, for example, reciprocating orpiston engines, rotary engines, and turbines. However, existing enginessuffer from a number of drawbacks. For example, conventional enginestypically include a compression step, compressing the oxidizer and, insome cases, the fuel. This compression step is energy-intensive andrequires the use of considerable starting energy and of heavycomponents. Reciprocating or piston engines also suffer from vibrationand energy losses due to the constant momentum change of the pistons asthey are repeatedly accelerated, stopped, and reversed during operationof the engine. Two-stroke reciprocating engines commonly intake fluidinto a chamber while that chamber is exhausting the combustion gasesfrom the previous cycle. Thus, the intake and/or exhaust may be openduring the power cycle, thereby shortening the power cycle and allowingsome unburned fuel to exhaust before combustion. Four-stroke enginessuffer from the disadvantage of only producing power every other cycle.Turbines also suffer from energy losses. For example, the intake processis typically open to the combustion chamber during combustion andtherefore the intake must overcome the opposing pressure of combustion.Additionally, turbines typically include an open channel from intake toexhaust, and thus do not efficiently harness energy when utilizingexternal pressure sources.

Internal rotary combustion engines offer some advantages over othertypes of engines. For example, internal rotary combustion engines aretypically more compact and include fewer moving parts, e.g., no valves,connecting rods, cams, and timing chains, than conventional pistonengines. Rotary engines also tend to operate more smoothly since thereis no reciprocating motion of the pistons. Additionally, rotary enginesmay have an extended power stroke rotation of the output shaft comparedto piston engines. However, typical rotary engines, such as Wankel-typeinternal combustion rotary engines, still suffer from a number ofdrawbacks. For example, many conventional rotary engines leak combustiongases, which is undesirable from a fuel efficiency and environmentalstandpoint. Additionally, many conventional rotary engines require anenergy-intensive compression step prior to ignition.

SUMMARY OF THE INVENTION

In accordance with one embodiment, a rotary internal combustion enginecomprises an outer housing and an inner housing disposed within theouter housing, at least one of the outer and inner housings beingrotatable relative to the other of the outer and inner housings andcomprising a drive member, first and second side housings disposed onopposite sides of the outer housing, and an enclosure is defined betweenan inner peripheral surface of the outer housing and an outer peripheralsurface of the inner housing. At least two barriers are disposed in theenclosure, and at least one of the barriers is rotatable relative to atleast one other barrier and at least one of the barriers comprises aretractable barrier mounted along a pivot axis and pivotable between anextended position in which the at least one retractable barrier extendsinto the enclosure and a retracted position in which the at least oneretractable barrier retracts from the extended position. The enclosureis divided into a combustion chamber and an exhaust chamber when the atleast one retractable barrier is in the extended position. The rotaryinternal combustion engine also includes an intake port for introducinga combustion fluid into the combustion chamber, an exhaust port forexhausting combustion gases from the exhaust chamber, and an ignitionsource disposed in the combustion chamber for igniting a mixture of fueland combustion fluid. The rotary internal combustion engine furtherincludes an intake opening formed in one of the side housings. Theintake opening is intermittently fluidly communicating with thecombustion chamber through the intake port.

In accordance with another embodiment, a rotary energy convertercomprises an outer housing and an inner housing disposed within theouter housing, at least one of the outer and inner housings beingrotatable relative to the other of the outer and inner housings andcomprising a drive member, first and second side housings disposed onopposite sides of the outer housing, and an enclosure is defined betweenan inner peripheral surface of the outer housing and an outer peripheralsurface of the inner housing. At least two barriers are disposed in theenclosure, at least one of the barriers is rotatable relative to atleast one other barrier and at least one of the barriers comprises aretractable barrier mounted along a pivot axis and is pivotable betweenan extended position in which the at least one retractable barrierextends into the enclosure and a retracted position in which the atleast one retractable barrier retracts from the extended position. Theenclosure is divided into at least two chambers when the at least oneretractable barrier is in the extended position. The rotary energyconverter also includes an intake port for introducing a fluid into oneof the at least two chambers, and an exhaust port formed in a top wallof the outer housing for axially exhausting fluid from another of the atleast two chambers. The rotary energy converter further includes anintake opening formed in one of the side housings. The intake opening isintermittently fluidly communicating with the combustion chamber throughthe intake port.

In accordance with another embodiment, a method of combusting a fuel ina rotary engine comprises rotating a drive member to expand a combustionchamber and substantially isolate the combustion chamber from an exhaustchamber, and introducing and combusting a combustion fluid and a fuel inthe combustion chamber as the combustion chamber is expanding.

The presently disclosed rotary internal combustion engine, energyconverter and method of combusting offer numerous advantages in the art.For example, the presently disclosed device is compact and efficient,and is adapted to perform multiple energy functions including harnessingenergy, storing energy, and recovering energy, and requires reducedstarting energy thereby making ‘idling’ less desirable. The device alsooperates at lower temperatures than many conventional engines and may beoperated with little or no additional cooling. The lower operatingtemperatures also may allow for pre-heating of a combustible fluidwithout pre-ignition, the use of lower quality fuels and the productionof fewer pollutants than many conventional internal combustion engines.Additionally, the device may include lighter weight components than manyconventional engines and operates with reduced back pressure, reducedexhaust noise, reduced (if not eliminated) starting energy and lessvibration as compared to other engines. The device also benefits fromincreased intake and exhaust volumetric efficiency. The device is alsoadapted to create a thrust stream. The thrust stream can be harnessedunder atmospheric conditions, as well as when atmospheric intake is notavailable. Since compression is not necessary, lower octane fuels can beused. Also, since the combustion chamber is expanding before combustion,fuel vaporization is improved, including the vaporization of hard tovaporize fuels. Advantageously, the vaporization also increases fuelefficiency, and cools the input charge and the engine. The expansionbefore combustion also advantageously provides the reduced pressure of acarburetor without a separate carburetor and without the intake drag ofa venturi-inducing flow restriction to the intake. Similarly, theexpansion before combustion may eliminate the need for a separate, highpressure fuel injector.

Other embodiments and features will become still further apparent fromthe ensuing description and appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an exploded view of an embodiment of a rotary combustionengine.

FIG. 1a is a sectional view of an embodiment of a retractable barrier.

FIG. 2a is a sectional view of an embodiment of a rotary combustionengine.

FIG. 2b is an isometric view of the rotary combustion engine of FIG. 2.

FIG. 3 is an isometric view of an embodiment of a combustion chamber.

FIG. 4 is an exploded view of another embodiment of a rotary combustionengine.

FIG. 5 is an isometric view of embodiment of a rotary combustion engineincluding an exhaust duct.

FIG. 6 is a sectional view of another embodiment of a rotary combustionengine.

FIG. 6a is an isometric view of an embodiment of a side housing.

FIG. 7 is a sectional view of an embodiment of a rotary combustionengine.

FIG. 8 is a sectional view of an embodiment of a rotary combustionengine.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Rotary energy converters according to the present disclosure may bevariously configured. In many embodiments, rotary energy converters maycomprise a rotary internal combustion engine 10 including an outerhousing 12 and an inner housing 14 centrally disposed within the outerhousing 12. A hollow enclosure 16 may be defined between an innerperipheral surface 22 of the outer housing 12 and an outer peripheralsurface 24 of the inner housing 14. The housings may have a variety ofconfigurations and in many embodiments the outer and inner housings arecylindrical. However, one or both housings may not be cylindrical, forexample the outer or inner housing may comprise an ellipse or parabolaor be irregularly shaped, so long as they define an enclosure betweentheir inner and outer surfaces, respectively. Additionally, theenclosure defined between the outer and inner housings may have avariety of cross-sections. For example, in the illustrated embodimentsthe rotary engine includes an outer housing top wall 18 and sidehousings 20 disposed on opposite sides of the top wall 18 which,together with the inner housing 14, create an enclosure 16 having arectangular cross-section. In other embodiments, the enclosure may haveother cross-sections. For example, the rotary engine may not include aseparate top wall and side housings and may include an outer housinghaving a semi-circular or parabolic shape, which together with the innerhousing, define an enclosure having a semi-circular or paraboliccross-section, respectively.

In accordance with the present disclosure the housings are oriented sothat at least one housing rotates relative to the other. For example,the inner housing 14 may rotate relative to a stationary outer housing12 (in which case the inner housing may operate as a drive member), theouter housing 12 may rotate relative to a stationary inner housing 14(in which case the outer housing may operate as a drive member), or theinner housing 14 and outer housing 12 may both rotate relative to oneanother, e.g., rotate in opposite directions. In embodiments includingside housings 20, one or both side housings may rotate or alternatively,they may be stationary. The energy from any or all of the relativelymoving parts may be harnessed, for example by connecting the moving partto a shaft and/or using the moving part as a shaft to produce work.Advantageously, the components of the presently disclosed device mayrotate in more than one direction, at the same time if desired, withoutthe use of complicated gears, which may be especially important inmarine and aviation applications. Also, since the power producingstructures may be cylindrical and input may occur from within the powerproducing structures, the device has a low frontal area, also especiallyimportant in marine and aviation applications.

The rotary engine also includes a plurality of barriers disposed in theenclosure between the outer housing and the inner housing. The barriersdivide the enclosure into a plurality of chambers, e.g., combustion andexhausting chambers and may extend into the enclosure in varyingamounts. For example, the barriers are preferably mounted to thesurfaces defining the enclosure, e.g., the inner peripheral surface ofthe outer housing, the outer peripheral surface of the inner housing,and/or an inner surface of a side housing, if present. The barriers mayextend substantially across the enclosure, providing little or noclearance between the barrier and an opposing surface and form asubstantially closed chamber. Alternatively, the barriers may extend toa lesser degree, for example, in the case of a rotating barrier thebarrier may extend only enough to provide rotation (e.g., when acted onby the combustion gases).

The plurality of barriers includes at least one barrier arranged torotate relative to at least one other barrier. For example, at least onebarrier may be mounted to a rotatable component while at least one otherbarrier may be mounted to a stationary or counter-rotating component. Insome embodiments, at least one barrier may be mounted to a rotatinginner housing and at least one other barrier may be mounted to astationary or counter-rotating outer housing. In other embodiments, atleast one barrier may be mounted to a rotating outer housing and atleast one other barrier may be mounted to a stationary orcounter-rotating inner housing. The plurality of barriers also includeat least one retractable barrier which is pivotably mounted to anenclosure surface and pivots between an extended position in which thebarrier extends into the enclosure and a retracted position in which thebarrier retracts from the extended position. For example, as best seenin FIGS. 1 and 2, a retractable barrier 30 may be mounted to the innerhousing outer peripheral surface 24 and may extend into the enclosure 16and may retract toward the inner housing 14. Additionally oralternatively (as shown in FIG. 6), a retractable barrier 30 may bemounted to the outer housing inner peripheral surface 22 and may extendinto the enclosure 16 and may retract toward the outer housing 12. Inthe retracted position, a retractable barrier 30 preferably retractsenough to allow the passage of another barrier (if the other barrier isrotating relative to the retractable barrier) or to pass another barrier(if the retractable barrier is rotating relative to the other barrier).In some embodiments, a retractable barrier 30 in the retracted positionmay lie substantially within a complementary recess 34 formed in thesurface to which it is mounted. However, in other embodiments theretracted barrier may retract to a lesser degree and need not lie withina recess.

The plurality of barriers may also include a fixed barrier, e.g., anon-pivoting barrier which does not retract from the extended positionin the enclosure. For example, in the embodiments illustrated in FIGS.1-4, the plurality of barriers comprises a fixed barrier 32 mounted tothe outer housing 12 (shown detached from the outer housing in FIGS. 1and 4 so as to be visible) and a retractable barrier 30 mounted to theinner housing. Since the fixed barrier does not retract, the retractablebarrier 30 retracts in order to pass or allow passage of the fixedbarrier 32. In other embodiments, and such as the embodiment illustratedin FIG. 7, the plurality of barriers may comprise two retractablebarriers 30. The two retractable barriers 30 may rotate relative to oneanother and both retractable barriers 30 may partially retract in orderto pass one another. In still other embodiments, the rotary engine mayinclude more than two barriers, for example, three, four or even moreretractable and/or fixed barriers. For example, in an embodimentillustrated in FIG. 8, the rotary engine includes two fixed barriers 32and two retractable barriers 30. In embodiments including multiple fixedbarriers, the rotary engine may also include multiple inlet ports andmultiple sources of fluid. For example, as seen in FIG. 8, a source ofcombustion fluid, e.g., an intake opening 27 in the side housing 20, isformed in a proximate region in front of (relative to clockwisemovement) each fixed barrier 32. Multiple intake ports 26 may also beformed in the inner housing 14, for example in the region of recesses 34to intermittently communicate with a source of combustion fluid.

A variety of mechanisms and combinations of mechanisms may be used toprovide the pivoting movement of the retractable barrier 30. Forexample, the barrier 30 may be extended by centrifugal force, such aswhen the retractable barrier 30 is mounted on a rotating inner housing14, or the barrier may be retracted by centrifugal force, for examplewhen the retractable barrier is mounted on a rotating outer housing 12.The retractable barrier 30 may also be retracted or extended by inertia,e.g., the inertia of its center of gravity, for example when RPM isincreasing (e.g. when storing energy) or is decreasing (e.g. whenrecovering energy). In FIG. 1a the combined center of gravity for theretractable barrier 30 and attached rod 54 is outside the rotationperimeter when extended and is inside the rotation perimeter whenretracted, thereby aiding positioning of the retractable barrier 30 whenRPM is changing.

Additionally or alternatively, the retractable barrier 30 may beextended or retracted by pressure, e.g., positive or negative pressurefrom above and/or below. For example, as seen in FIG. 1a , a void may bepresent under the retracted retractable barrier 30, allowing positive ornegative pressure from below to extend or retract the barrier 30. Thebarrier may also be refracted by contact with another barrier, forexample contact with a fixed or retractable barrier. Additionally oralternatively, as shown in FIGS. 1 and 1 a, one of the outer housingside walls may include a continuous cam groove 50 which receives a pin52 on the retractable barrier 30 for providing control of the pivotingmovement of the retractable barrier 30. For example, the cam groove 50may be formed substantially along the perimeter of the side housinguntil it approaches the fixed barrier 32. In order for the retractablebarrier 30 to pass under the fixed barrier 32, the cam groove 50 maydepart from the perimeter and follow a path corresponding to theconfiguration of the fixed barrier 32, as seen in FIG. 1.Advantageously, in each of these embodiments very little energy isrequired to extend and/or retract the retractable barriers. For example,when the retractable barrier 30 extends or retracts the center ofgravity of the retractable barrier 30 only moves a short distance, e.g.,from the edge of the enclosure 16 to the center of the enclosure 16 orvice versa. Furthermore, as the retractable barrier 30 mounted to theinner housing 14 retracts, the angular velocity of the rotatingcomponent to which it is mounted is accelerated, increasing the overallefficiency of the device.

In some embodiments, and as seen in FIG. 1a , the retractable barrier 30may also include a rod 54 which limits the extension of the retractablebarrier 30. The rod 54 advantageously minimizes friction between theretractable barrier 30 and any opposing surface not moving with theretractable barrier 30 which it contacts in the extended position.Although the rod 54 is shown on the retractable barrier 30 including thepin 52 for controlling pivoting movement, it may be used on otherembodiments as well. For example, the rod 54 may be used in embodimentswhere the retractable barrier is extended and/or retracted bycentrifugal force, pressure, and/or contact with another barrier.

The retractable barriers may have a variety of configurations. In manyembodiments, it may be desirable to have retractable barriers having anouter perimeter that closely matches the cross-section of the enclosure.For example, a retractable barrier extending substantially across theenclosure and having an outer perimeter that closely matches theenclosure cross-section may advantageously form a substantially closedchamber. In the illustrated embodiments including enclosures havingrectangular cross-sections, a retractable barrier having a substantiallyrectangular perimeter may be utilized to form a substantially closedchamber. In embodiments including enclosures having othercross-sections, other retractable barrier configurations may bepreferred. For example, embodiments including a semi-circular orparabolic enclosure may utilize a retractable barrier having asemi-circular or parabolic perimeter, respectively. A retractablebarrier having a semi-circular configuration may provide otheradvantages as well. For example, a semi-circular barrier may increasethe cross-section to perimeter ratio and may further reduce friction inthe device. However, the retractable barriers need not have outerperimeters that match the cross-section of the enclosure so long as theycan rotate within the enclosure.

The rotary internal combustion engine may also include an intake portwhich may communicate with a source of combustion fluid, e.g., a sourceof oxidizer and the hollow enclosure for introducing combustion fluidinto the enclosure. In some embodiments, a fuel may also be introducedvia the intake port, e.g., as a pre-mix with the combustion fluid. Inother embodiments, the fuel may not be introduced via the intake port,but may be introduced via a fuel injector communicating with thecombustion chamber.

In many embodiments, the intake port may intermittently communicate withthe source of combustion fluid so that fluid is only intermittentlyintroduced into the enclosure. For example, as best seen in FIG. 2a , insome embodiments the intake port 26 may be formed in the inner housing14, for example as a recess in the sidewall of the inner housing 40. Thesource of combustion fluid may comprise an intake opening 27 in one ofthe side housings 20. The side housing opening 27 may be positioned sothat as the inner housing 14 rotates relative to the side housing 20,the intake opening 27 may be blocked by a sidewall 40 of the innerhousing 14 (as illustrated in FIG. 2a ) except when the intake port 26overlaps the intake opening 27. In other embodiments the source ofcombustion fluid may be oriented within the inner housing andintermittently communicate with an intake port 26 formed in the innerhousing. For example, as best seen in FIG. 4, a shaft 42 may be orientedinside the inner housing 14, for example oriented substantiallycoaxially with the inner housing 14, and may include an opening 44through which combustion fluid may be introduced. As the inner housing14 rotates, the shaft opening 44 may be blocked by the inner peripheralsurface of the inner housing 46 until the intake port 26 overlaps theopening 44. As the intake port 26 overlaps the opening 44, combustionfluid may be introduced to the hollow enclosure 16 via the intake port26. In some embodiments, combustion fluid may be introduced into theenclosure via both of the above-described combustion fluid sources.Advantageously, the intake port configurations allow a large input flowcross-section increasing volumetric efficiency, as well as providingdiverse input options.

The rotary engine may also include an exhaust port. The exhaust port mayhave a variety of configurations and may be formed in a number oflocations. In many embodiments, and as best seen in FIGS. 1, 2, and 3,an exhaust port 28 may be formed in the outer housing 12. For example,an exhaust port 28 may comprise an opening in the outer housing 12 whichcommunicates with the hollow enclosure 16. Exhausting axially throughthe outer housing 12 advantageously reduces the backpressure in theengine by utilizing centrifugal force and thereby increasing efficiency.In some embodiments, and illustrated in FIG. 5, an exhaust port 28 mayinclude an exhaust duct 29. The exhaust duct 29 may extend from withinthe hollow enclosure 16 to outside the outer housing 12 tangent to thedirection of flow in the hollow enclosure 16. In many embodiments, theexhaust duct 29 may have substantially the same cross-section as thehollow enclosure 16. The exhaust duct 29 advantageously allows thecombustion gases to flow from the enclosure 16 out of the exhaust 28without changing direction and/or cross-section, allowing the drive unitto turn with more power and/or allowing a higher thrust stream.

The embodiments illustrated in the Figures will now be described in moredetail. In the embodiment illustrated FIGS. 1 and 2, the rotary engine10 includes an inner housing 14 rotatably disposed within an outerhousing 12, a fixed barrier 32 mounted to the inner peripheral surfaceof the outer housing 22 and retractable barrier 30 pivotably mounted tothe outer peripheral surface of the inner housing 24. The barriers 30,32 extend substantially into the enclosure, i.e., only a small degree ofclearance exists between the barriers and their opposing surfaces, andthe retractable barrier 30 retracts to a position substantially within arecess 34 formed in the inner housing 14. However, the barriers mayalternatively extend into the enclosure to a lesser degree and theretractable barrier 30 need not retract into a recess, but may simplyretract in the direction of the surface to which it is mounted to adegree sufficient to allow the passage of the other barrier.

The hollow enclosure 16 is divided into a combustion chamber 36comprising a region in front of (relative to clockwise movement) thefixed barrier 32 and behind the retractable barrier 30 and an exhaustingchamber 38 comprising a region in front of (relative to clockwisemovement) the retractable barrier 30 and behind the fixed barrier 32. Inoperation, the retractable barrier 30 is extended as it rotates with theinner housing 14 until it comes into contact with the fixed barrier 32.As the retractable barrier 30 contacts the fixed barrier 32, it moves tothe retracted position and passes under the fixed barrier 32. Afterpassing under the fixed barrier 32, the retractable barrier 30 againpivots to an axially extended position, for example, as a result ofcentrifugal force, pressure applied from under the retracted barrier, apin and groove or some other combination. Advantageously, theretractable barrier 30 moves with its attached enclosure surface, i.e.,the inner housing 14 thereby minimizing friction between moving parts ofthe device. In some embodiments, the side housings 20 may also rotatewith the retractable barrier 30 further reducing friction in the device.

The source of combustion fluid may comprise an intake opening 27 formedin one of the side housings 20 which may intermittently communicate withthe hollow enclosure 16 to introduce combustion fluid into theenclosure. For example, the intake opening 27 may be positioned so thatas the inner housing 14 rotates relative to the side housing 20, theintake opening 27 is blocked by a sidewall of the inner housing 14except when the recess 34 overlaps the intake opening 27. As the recessoverlaps the intake opening 27, the recess forms an intake port 26allowing the introduction of combustion fluid into the hollow enclosure16. Fuel may also be introduced with the combustion fluid via the intakeport 26, or as shown in FIG. 3, a fuel injector 25 may introduce fuel tothe enclosure 16. As the recess 34 moves beyond the intake opening 27,the hollow enclosure 16 is again isolated from the combustion fluidsource. The intake opening 27 is also preferably formed in a proximateregion in front of (relative to clockwise movement) the fixed barrier32, e.g., to communicate with the combustion chamber. In thisconfiguration, the source of combustion fluid communicates with thehollow enclosure 16 as the retractable barrier 30 returns to an axiallyextended position and as the combustion chamber 36 is formed.Accordingly, the combustion chamber 36 may be substantially isolatedduring the intake stage, so that the intake does not have to overcomethe pressure of combustion. As the combustion fluid is introduced, theinner housing 14 continues to rotate, moving the retractable barrier 30forward and expanding the combustion chamber 36 and providing a lowerpressure environment due to the combustion chamber 36 expansion. Thisexpansion allows for increased vaporization and thereby improvedcombustion, as well as allowing for the use of harder to vaporize fuels.Furthermore, since the chamber is not contracting after intake, e.g.,the fluid is not being compressed, lower octane fuels may be used andincreased vaporization obtained. When the source of combustion fluid nolonger communicates with combustion chamber 36, combustion may occur ina closed or substantially closed chamber, efficiently utilizing thecombustion. As seen in FIG. 3, an ignition source 23, e.g., a sparkplug, may be present in the combustion chamber 36 to ignite the fuelmixture and initiate combustion. The combustion chamber 36 continues toexpand after combustion, e.g., via the continued rotation of the innerhousing, until the retractable barrier 30 has made a revolution andagain contacts the fixed barrier 32. Advantageously, this continuingexpansion of the combustion chamber 36 and expansion of the fluidmixture provides a cooling effect allowing the engine 10 to operate atreduced temperatures. The absence of a compression step providesadditional advantages as well. For example, the operation of the deviceis less energy intensive, allowing for low-energy idle, reduced (if noteliminated) starting energy and the use of components made from lightermaterials. Additionally, because combustion is expanding tangent torotation, the device also operates with less vibration and can operateunder increased loads, as compared to many conventional engines. Forexample, piston engines operating under a high load may experienceabrupt movements known as “bucking”, a difficulty which may be avoidedwith the presently disclosed device. “Bucking”, a significant vibration,usually occurs under high loads and/or low rpm when two connected partsare not acting in the same direction, e.g. a piston and a crankshaft.

The exhaust port 28 may be located in the outer housing top wall 18 in aregion at or behind (relative to clockwise movement) the fixed barrier32. In operation, the exhaust port 28 may communicate with the hollowenclosure 16 during the revolution of the inner housing 14. For example,starting when the combustion chamber 36 is formed, e.g., as theretractable barrier 30 passes the fixed barrier 32 and returns to anaxially extended position, the exhaust port 28 is in communication withthe exhausting chamber 38. The exhaust port 28 remains in communicationwith the exhausting chamber 38 until the retractable barrier 30 passesthe exhaust port 28 bringing the combustion chamber 36 intocommunication with the exhaust port 28. Thus, the combustion gases fromeach previous combustion cycle may be continually exhausted, therebyreducing backpressure and increasing efficiency.

In another embodiment, best seen in FIG. 4, the engine 10 may beconfigured similarly to the above-described embodiment but the intakeport 26 may comprise an opening extending through the inner housing 14,for example, from an inner peripheral surface of the inner housing 46 tothe outer peripheral surface of the inner housing 24. A shaft 42 may beoriented inside the inner housing 14, for example oriented substantiallycoaxially with the inner housing 14, and may include an opening 44through which combustion fluid may be introduced. As the inner housing14 rotates, the shaft opening 44 may be blocked by the inner peripheralsurface of the inner housing 46 until the intake port 26 overlaps theopening 44. As the intake port 26 overlaps the opening 44, combustionfluid may be introduced to the hollow enclosure 16 via the intake port26. Introducing the combustion fluid through the centrally located shaftoffers a number of advantages. For example, as seen in FIG. 4, the shaft42 may also include a plurality of additional openings 48, e.g., holesthrough which combustion fluid may flow to create a fluid bearing effectbetween the shaft 42 and inner housing 14. Additionally oralternatively, conventional friction reduction methods, e.g. bearings,lubricants etc. may be used. In other embodiments, the combustion fluidmay not be introduced through the shaft 42, but the shaft 42 may includethe plurality of openings 48 through which combustion fluid may flow tocreate a fluid bearing effect. In the embodiment shown in FIG. 4, someof the openings 48 will overlap the intake port 26 after intake andduring combustion so that the combustion chamber is not completelyisolated from the intake during combustion. However, in some embodimentsthe shaft 42 may not include the openings 48 located in the region whichoverlaps the intake port 26. Additionally, the centrifugal force actingon the fluid between the shaft 42 and inner housing 14 may acceleratethe fluid, drawing fluid through the opening 44. Opening 44 may alsooperate as exhaust by positioning opening 44 to overlap port 26 duringexhaust instead of during intake.

In another embodiment illustrated in FIGS. 6 and 6 a, the rotary enginemay be configured similarly to the embodiment illustrated in FIGS. 1 and2, but the rotary engine 10 may include an outer housing 12 rotatablydisposed around an inner housing 14. The outer housing 12 may be a shaftand/or connected to a shaft (not shown) for producing work. A fixedbarrier 32 may be mounted to the inner housing 14 and a retractablebarrier 30 may be mounted to the inner peripheral surface of the outerhousing 22. The retractable barrier 30 may pivot between an axiallyextended position in which it extends into the hollow enclosure 16 and aretracted position in which it lies substantially within a recess 34formed in the inner peripheral surface of the outer housing 22. Inoperation, the retractable barrier 30 rotates with the rotation of theouter housing 12 in the extended position until it comes into contactwith the fixed barrier 32. As the retractable barrier 30 contacts thefixed barrier 32, it moves to the retracted position and passes underthe fixed barrier 32 and after passing under the fixed barrier 32, theretractable barrier 30 again pivots to an axially extended position.

The source of combustion fluid may comprise an intake opening 27 formedin one of the side housings 20 (shown in FIG. 6a ) and the intake port26 may be formed in the outer housing 12, for example in a side wall 41of the outer housing 12. In many embodiments the recess 34 may operateas an intake port 26. In operation, as the outer housing 12 rotates, theopening 27 may be blocked by the sidewall 41 of the outer housing 12until the intake port 26, e.g., the recess 34 overlaps the intakeopening 27. As the intake port 26 overlaps the intake opening 27, thehollow enclosure 16 may be open to the source of combustion fluid whichmay be introduced through the intake port 26. As the intake port 26moves beyond the intake opening 27, the hollow enclosure 16 is againclosed to the intake combustion fluid stream.

The exhaust port may be formed in the outer housing top wall 18 and/orin one of the side housings 20. For example, in some applications it maybe desirable to utilize a rotating exhaust stream, in which case anexhaust port formed in the rotating outer housing top wall 18 or in theform of an exhaust duct as illustrated in FIG. 5 may be desired. Inother embodiments, it may be preferred to utilize a stationary exhaustport in which case the exhaust port 28 may be located in one of the sidehousings 20. In order to achieve a substantially closed combustionchamber, the exhaust port is preferably located after (in the directionof rotation) the retractable barrier 30. Additionally, it may bedesirable to utilize multiple exhaust ports, for example to increase thevolumetric efficiency of the exhaust, in which case exhaust ports may beformed in both the outer housing and a side housing.

In another embodiment illustrated in FIG. 7, the rotary engine mayinclude two retractable barriers and may not include a fixed barrier.For example, the engine 10 may include a retractable barrier 30pivotably mounted to the inner housing 14 and another retractablebarrier 30 pivotably mounted to the outer housing 12. In the illustratedembodiment, the retractable barrier 30 mounted to the inner housing 14may rotate in the extended position relative to the extended barrier 30mounted to the outer housing 12. Centrifugal force may extend thebarrier 30 mounted to the inner housing 14 and other means, for examplepressure from below may be used to extend the retractable barrier 30mounted to the outer housing 12. The barriers 30 may refract, e.g.,partially refract, as the rotating retractable barrier passes andcontacts the non-rotating retractable barrier. In other embodiments, theouter housing retractable barrier may rotate or both barriers mayrotate, e.g., in opposite directions, in the extended position andretract, e.g., partially retract as they pass each other. The intakeport 26 and exhaust port(s) 28 may be configured in accordance with anyof the above-described embodiments.

In another embodiment illustrated in FIG. 8, the rotary engine 10 may beconfigured similarly to the embodiments illustrated in FIG. 1-2 or 3,but may include two retractable barriers 30 and two fixed barriers 32.The two retractable barriers 30 may be pivotably mounted to the innerhousing 14 and the fixed barriers 32 may be mounted to the innerperipheral surface of the outer housing 22. In the axially extendedposition, the two retractable barriers 30 and the two fixed barriers 32may divide the hollow enclosure 16 into two combustion chambers 36 andtwo exhausting chambers 38. Two sources of combustion fluid and twointake ports may provide fluid to each combustion chamber. For example,in the illustrated embodiment, openings 27 formed in the side housing 20in front of (relative to clockwise movement) each fixed barrier comprisea source of combustion fluid for each combustion chamber. Recesses 34under each retractable barrier 30 may operate as intake ports andintermittently communicate with the openings 27 to introduce combustionfluid into the combustion chambers. Additionally or alternatively, thesource of combustion fluid may be disposed within the inner housing andthe intake port may be formed in the inner housing, for example, inaccordance with the embodiment illustrated in FIG. 4.

In addition to multiple combustion chambers formed in a singleenclosure, in some embodiments, multiple combustion chambers may bepositioned longitudinally along the axis. For example, a plurality ofenclosures according to the present disclosure including one or morecombustion chambers may be oriented along a common axis. In someembodiments the intake ports for the plurality of enclosures may beoffset from one another, so that the cycles of the enclosures areoffset, allowing for a self-start of an engine.

Rotary engines may combust fuels using a variety of methods. Inaccordance with one embodiment, a combustion fluid may be introducedinto a combustion chamber as the combustion chamber is expanding. Forexample, using the embodiment shown in FIGS. 1 and 2 for reference, acombustion fluid may be introduced into the combustion chamber 36through the opening 27 and intake port 26. As the fluid is introduced,the inner housing 14 continues to rotate and the retractable barrier 30continues to move forward, thus expanding the combustion chamber 36. Afuel may be introduced into the combustion chamber with the combustionfluid, e.g., as a pre-mix, or fuel may be introduced directly into thecombustion chamber, e.g. as fuel injection. Advantageously, theexpanding combustion chamber 36 allows for increased vaporization offuel in the combustion chamber and allows for the use of harder tovaporize fuels and lower octane fuels. In many embodiments, thecombustion fluid and fuel mixture within the combustion chamber may beignited as the chamber 36 continues to expand. For example, as theretractable barrier 30 continues to move forward and the combustionchamber 36 continues to expand, the fluid mixture in the combustionchamber 36 may be exposed to an ignition source. The ignition of thevaporized fuel produces combustion gases which push the retractablebarrier 30 forward moving the inner housing 14 (or in some embodimentsthe outer housing 12). The forward motion of the retractable barrier 30also pushes any fluid from the previous cycle (exhaust) in front of theretractable barrier 30, e.g., in the exhausting chamber 38 and outthrough the exhaust port 28. After the combustion of the fuel, thecombustion chamber 36 may communicate with the exhaust port 28,exhausting any combustion gases from the combustion chamber 36. Forexample, the combustion chamber 36 may communicate with the exhaust port28 as the retractable barrier 30 approaches the fixed barrier 32. As theretractable barrier 30 approaches or contacts the fixed barrier 32, theretractable barrier 30 may move to an axially retracted position. In theretracted position, the retractable barrier 30 passes under the fixedbarrier 32; the cycle then starts again and is repeated as describedabove.

Although the above-described embodiments utilize combustion gases todrive the retractable barrier and drive member forward, the invention isnot so limited. In some embodiments, other sources of pressure,including but not limited to geo-thermal pressure, hydraulic pressure,and steam pressure may be utilized. In these embodiments, thepressurized fluid drives the retractable barrier forward to expand intothe enclosure volume similar to the pressurized fluid in a reciprocatingsteam engine. In these embodiments, the duration of overlap between theintake port and fluid source opening and/or the size of the intake portand/or fluid source openings may be increased to sustain the pressure.Additionally or alternatively, other intake port configurations may beutilized. Advantageously, the present device allows the energy of thepressurized fluid to be efficiently harnessed without the energy lossesdue to the reciprocating mass found in reciprocating/pistonconfigurations. Additionally, the retractable barrier effectively closesthe expanding chamber in contrast with turbines which typically includean open channel for the pressurized fluid to expand/flow by simplyfollowing an open channel from intake to exhaust when external pressureis applied.

In some embodiments, the device may be operated as a pump. For example,the device may operate as a fluid pump for negative pressure, e.g., forfluid in the first chamber and/or for positive pressure, e.g., for fluidin the second chamber. In these embodiments, one end of the pressurechamber is closed. If used for negative pressure, the “expanding” end ofthe first chamber, e.g., at the retractable barrier is substantiallyclosed creating an efficient vacuum and negative pressure. If used forpositive pressure, the “contracting” end of the second chamber issubstantially closed, and the fluid is efficiently forced to move and/orpressurize under pressure. Advantageously, the presently discloseddevice operates efficiently as a pump without the energy losses andvibration of reciprocating/piston pumps, and with the closed end that islacking in turbine pumps.

The present device may also be efficiently utilized as a flywheel tostore energy. In these embodiments, the retractable barrier may bemaintained in a retracted position to reduce any resistance toacceleration and/or to movement, thus increasing efficiency. Forexample, in some embodiments pressure may be used to extend the barrier,and in these embodiments the retractable barrier may be maintained in aretracted position using negative pressure. Alternatively, in someembodiments, such as those utilizing an intake port on the outer housingtop wall, centrifugal force may be utilized to maintain the retractablebarrier in a retracted position.

In some embodiments, the exhaust may be harnessed to produce work. Forexample, the exhaust may be used to drive a turbine. In otherembodiments propellers or foils may be directly attached to the drivemember. Additionally, the exhaust may be used by itself to drive otherenergy conversion devices or to create a high pressure air flow, e.g. athrust stream. Advantageously, the presently disclosed device may beeffectively and efficiently used to create a thrust stream in bothatmospheric use, i.e. using atmospheric intake, and non-atmospheric use,i.e., using ‘rocket’ fuel, unlike many conventional devices. In anembodiment using the device to create a thrust stream, the device mayinclude an exhaust duct with the same cross-section as the enclosure toincrease volumetric efficiency. For example, the exhaust duct on theexhaust side may provide a constant exhaust stream cross-section frominside the enclosure to outside the enclosure, so that the exhaustcross-section does not have to change as the exhaust exits the device.Additionally, exhaust direction does not have to change as it is stilltangent to the direction of flow in the enclosure. Furthermore, thrustvectoring may be achieved by rotating the device on its operating axisto essentially rotate the exhaust point.

The presently disclosed rotary energy converters effectively andefficiently harness energy in a number of ways. For example, in someembodiments the rotation of the device retracts the retractable barrier,and thus the energy that was used to extend the retractable barrier maybe put back into the system due to the conservation of angular momentum.The retractable barrier also travels a shorter distance than manymovable devices used for creating a cross section barrier, since thebarrier center of gravity moves from approximately on an enclosureinterior surface to approximately halfway across the enclosure. Inembodiments where the device comprises an internal combustion engine,the combustion chamber is substantially closed and the combustionpressure pushes the retractable barrier and efficiently harnesses thecombustion energy. Additionally, in accordance with the presentdisclosure the intake process may not be exposed to the pressure ofcombustion since the combusted fluids from the previous cycle may havebeen substantially exhausted from the enclosure at the intake, andcombustion may be delayed until the intake is closed. As anotheradvantage, the pressurized fluids apply a force to the barriers directlyin a line of motion (a tangent line) of the driven device, therebyefficiently harnessing the combustion pressure. This is in contrast to,for example, connecting rods, where the pressure is applied at an angleto the tangent. Additionally, the present invention produces power onevery cycle without having the chamber open to the exhaust and intake atthe same time.

In some embodiments the present device may be accelerated to brake orslow another device and the presently disclosed device may be used tostore the braking energy by storing pressure, e.g., positive and/ornegative and/or by use as a flywheel. Thus, regenerative braking, e.g.,storing energy, and engine power, e.g., harnessing energy may beaccomplished with the same device. The energy may then be used, e.g.,recovering energy, the same as when used as an engine. In contrast, mostregenerative braking configurations require separate energy harnessing,storage, and recovery devices. Furthermore, essentially all of therotating engine mass would store flywheel energy, making excellent useof the engine mass and cost. The low starting energy also makes engineshutoff/restart (for fuel consumption, pollution and noise benefits)more feasible. Indeed the invention could be configured to have acombustion chamber situated in the ignition position wherever the enginestops, e.g. if multiple chambers and/or enclosures were used, allowing aself-start. Alternatively, for a single combustion chamber, other meanscould be used, such as pressure to allow a self-start. In either caseself-starting is assisted because of the low starting energy and because“bucking” is reduced by lack of compression and fluid pressure appliedtangent to rotation.

The presently disclosed device offers numerous other advantages as well.For example, the present device has few moving parts and reducescomplexity compared to many systems used for similar purposes. In someembodiments, the combustion gases may be exhausted axially outward andaided by centrifugal force, thereby reducing backpressure and increasingoutput. Furthermore, the combustion gases, retractable barrier, andexhaust all flow in the same direction further increasing the efficiencyof the device. If braking is accomplished without using the flywheelaspect, then energy could be stored without increasing rpm, therebydecreasing wear.

This invention is susceptible to considerable variation in its practice.Therefore the foregoing description is not intended to limit, and shouldnot be construed as limiting, the invention to the particularexemplifications presented hereinabove. Rather, what is intended to becovered is as set forth in the ensuing claims and the equivalentsthereof permitted as a matter of law.

What is claimed is:
 1. A rotary internal combustion engine comprising:an outer housing and an inner housing disposed within the outer housingso as to define an enclosure between an inner peripheral surface of theouter housing and an outer peripheral surface of the inner housing, atleast one of the outer and inner housings being rotatable relative tothe other of the outer and inner housings so as to define a drivemember; first and second side housings disposed on opposite sides of theouter housing; at least two barriers disposed in the enclosure, at leastone of the barriers being rotatable relative to at least one otherbarrier and at least one of the barriers comprising at least tworetractable barriers mounted along a pivot axis and being pivotablebetween an extended position in which the at least two retractablebarriers extend into the enclosure and a retracted position in which theat least two retractable barriers retract from the extended position,the enclosure being divided into a combustion chamber and an exhaustchamber when the at least one of the at least two retractable barriersis in the extended position; an intake port for introducing a fluid intothe combustion chamber; an intake opening formed in one of the sidehousings, the intake opening intermittently fluidly communicating withthe combustion chamber through the intake port; an exhaust port forexhausting combustion gases from the exhaust chamber; and an ignitionsource disposed in the combustion chamber for igniting a mixture of fueland combustion fluid.
 2. The rotary internal combustion engine accordingto claim 1, further comprising a fuel injector disposed in thecombustion chamber for introducing a fuel into the combustion chamber.3. The rotary internal combustion engine according to claim 1, whereinthe at least two barriers comprise a first barrier, a first retractablebarrier, a second barrier and a second retractable barrier; the firstbarrier extends into the enclosure and the first retractable barrier ispivotable between an extended position and a retracted position, atleast one of the first barriers being rotatable relative to the otherfirst barrier; the second barrier extends into the enclosure and thesecond retractable barrier is pivotable between an extended position andretracted position, at least one of the second barriers being rotatablerelative to the other second barrier, wherein the enclosure is dividedinto first and second combustion chambers and first and second exhaustchambers with the first and second retractable barriers are extended. 4.The rotary internal combustion engine according to claim 1, wherein atleast one of the side housings rotates relative to at least one of theinner and outer housings.
 5. The rotary internal combustion engineaccording to claim 1, wherein the exhaust port is formed in a top wallof the outer housing.
 6. The rotary internal combustion engine accordingto claim 1, further comprising an exhaust duct extending from within theenclosure to outside the outer housing in a direction tangent to flow inthe enclosure.
 7. The rotary internal combustion engine according toclaim 1, further comprising an exhaust duct extending from within theenclosure to outside the outer housing having a cross-sectionsubstantially the same as a cross-section of the enclosure.
 8. Therotary internal combustion engine according to claim 1, wherein theouter and inner housings rotate in opposite directions.
 9. The rotaryinternal combustion engine according to claim 1, wherein at least one ofthe barriers is mounted to one of the side housings.
 10. The rotaryinternal combustion engine according to claim 1, wherein each of theretractable barriers pivots between the extended position and theretracted position by centrifugal force and/or the inertia of theretractable barrier.
 11. The rotary internal combustion engine accordingto claim 1, wherein each of the retractable barriers is mounted to thedrive member and is pivotable between the extended position and theretracted position by the action of a continuous cam groove formed inone of the side housings; and wherein each of the retractable barriershas a pin laterally extending from the retractable barrier and engagingthe continuous cam groove.
 12. The rotary internal combustion engineaccording to claim 1, wherein the intake port is formed in one of theinner housing and the outer housing to intermittently overlap the intakeopening.
 13. The rotary internal combustion engine according to claim12, wherein the intake port is in the form of a recess on one of theinner housing and the outer housing; the intake opening isintermittently overlapped by the intake port or blocked by a sidewall ofone of the inner housing and the outer housing.
 14. A rotary energyconverter comprising: an outer housing and an inner housing disposedwithin the outer housing so as to define an enclosure between an innerperipheral surface of the outer housing and an outer peripheral surfaceof the inner housing, at least one of the outer and inner housings beingrotatable relative to the other of the outer and inner housings so as todefine a drive member; first and second side housings disposed onopposite sides of the outer housing; at least two barriers disposed inthe enclosure, at least one of the barriers being rotatable relative toat least one other barrier and at least one of the barriers comprisingat least two retractable barriers mounted along a pivot axis and beingpivotable between an extended position in which the at least tworetractable barriers extend into the enclosure and a retracted positionin which the at least two retractable barriers retract from the extendedposition, the enclosure being divided into at least two chambers whenthe at least one of the at least two retractable barriers is in theextended position; an intake port for introducing a fluid into one ofthe at least two chambers; an intake opening formed in one of the sidehousings, the intake opening intermittently fluidly communicating withthe one of the at least two chambers through the intake port; and anexhaust port formed in a top wall of the outer housing for axiallyexhausting fluid from another of the at least two chambers.
 15. Therotary energy converter according to claim 14, further comprising anexhaust duct extending from within the enclosure to outside the outerhousing in a direction tangent to flow in the enclosure.
 16. The rotaryenergy converter according to claim 14, further comprising an exhaustduct extending from within the enclosure to outside the outer housinghaving a cross-section substantially the same as the enclosurecross-section.
 17. The rotary energy converter according to claim 14,wherein the outer and inner housings rotate in opposite directions. 18.The rotary energy converter according to claim 14, wherein at least oneof the barriers is mounted to one of the side housings.
 19. The rotaryenergy converter according to claim 14, wherein each of the retractablebarriers is mounted to the drive member and is pivotable between theextended position and the retracted position by the action of acontinuous cam groove formed in one of the side housings; and whereineach of the retractable barriers has a pin laterally extending from theretractable barrier and engaging the continuous cam groove.
 20. A rotaryinternal combustion engine comprising: an outer housing and an innerhousing disposed within the outer housing so as to define an enclosurebetween an inner peripheral surface of the outer housing and an outerperipheral surface of the inner housing, at least one of the outer andinner housings being rotatable relative to the other of the outer andinner housings so as to define a drive member; first and second sidehousings disposed on opposite sides of the outer housing; at least twobarriers disposed in the enclosure, at least one of the barriers beingrotatable relative to at least one other barrier and at least one of thebarriers comprising a retractable barrier mounted along a pivot axis andbeing pivotable between an extended position in which the at least oneretractable barrier extends into the enclosure and a retracted positionin which the at least one retractable barrier retracts from the extendedposition, the enclosure being divided into a combustion chamber and anexhaust chamber when the at least one retractable barrier is in theextended position; an intake port for introducing a fluid into thecombustion chamber; an intake opening formed in one of the sidehousings, the intake opening intermittently fluidly communicating withthe combustion chamber through the intake port; an exhaust port forexhausting combustion gases from the exhaust chamber; an ignition sourcedisposed in the combustion chamber for igniting a mixture of fuel andcombustion fluid; and a rod connecting the retractable barrier to theinner housing so as to limit the extension of the retractable barrieraway from the inner housing.
 21. A rotary energy converter comprising:an outer housing and an inner housing disposed within the outer housingso as to define an enclosure between an inner peripheral surface of theouter housing and an outer peripheral surface of the inner housing, atleast one of the outer and inner housings being rotatable relative tothe other of the outer and inner housings so as to define a drivemember; first and second side housings disposed on opposite sides of theouter housing; at least two barriers disposed in the enclosure, at leastone of the barriers being rotatable relative to at least one otherbarrier and at least one of the barriers comprising a retractablebarrier mounted along a pivot axis and being pivotable between anextended position in which the at least one retractable barrier extendsinto the enclosure and a retracted position in which the at least oneretractable barrier retracts from the extended position, the enclosurebeing divided into at least two chambers when the at least oneretractable barrier is in the extended position; an intake port forintroducing a fluid into one of the at least two chambers; an intakeopening formed in one of the side housings, the intake openingintermittently fluidly communicating with the one of the at least twochambers through the intake port; an exhaust port formed in a top wallof the outer housing for axially exhausting fluid from another of the atleast two chambers; and a rod connecting the retractable barrier to theinner housing so as to limit the extension of the retractable barrieraway from the inner housing.